Magnetoresistive Point Field Detector-based Current Sensing for Power Electronics with Bandwidth Extension

2019 IEEE SENSORS Pub Date : 2019-10-01 DOI:10.1109/SENSORS43011.2019.8956625

Muhammad H. Alvi, Minhao Sheng, R. Lorenz, T. Jahns

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引用次数: 1

Abstract

Giant Magnetoresistive (GMR) point field detectors (PFDs) have been integrated into power electronic converters for high-bandwidth galvanically-isolated current sensing in conductors that are especially designed for magnetic field shaping. In this work, a methodology is introduced to sense currents in standard conductors with very high bandwidth by detecting the magnetic field as a vector in multi-dimensional space. Tools are developed to identify the field components in directions that do not have frequency-dependent changes arising from skin effect in the conductors. The importance of orienting the PFD in a particular point is identified as critical to the flat frequency response of current sensing. In this paper, bandwidth extension for busbar current sensing is experimentally verified by sensing the magnetic field using a rotated 1-D GMR as well as by computing the same magnetic field vector from orthogonal X and Y outputs of a 2-D GMR PFD. Current sensing bandwidth extension using the multi-dimensionality of the magnetic field leads to compact, low-cost current sensing without complicated conductor designs.

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基于磁阻点场探测器的带宽扩展电力电子电流传感

巨磁阻(GMR)点场探测器(pfd)已被集成到电力电子变换器中，用于高带宽电隔离电流传感，特别是为磁场成形而设计的导体。在这项工作中，介绍了一种方法，通过在多维空间中检测作为矢量的磁场来检测具有非常高带宽的标准导体中的电流。开发了工具来识别方向上的场分量，这些方向没有由导体中的趋肤效应引起的频率相关变化。将PFD定向在特定点上的重要性被认为是电流传感平坦频率响应的关键。本文通过实验验证了母线电流传感的带宽扩展，通过使用旋转的1-D GMR以及通过从2-D GMR PFD的正交X和Y输出计算相同的磁场矢量来传感磁场。利用磁场的多维度扩展电流传感带宽，可以实现紧凑、低成本的电流传感，而无需复杂的导体设计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2019 IEEE SENSORS

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